WO2022189722A1

WO2022189722A1 - Expansion valve comprising a movable slide

Info

Publication number: WO2022189722A1
Application number: PCT/FR2022/050336
Authority: WO
Inventors: Benoit Gresset; Loïc JOLY; Sébastien ROBERT
Original assignee: Schrader
Priority date: 2021-03-08
Filing date: 2022-02-24
Publication date: 2022-09-15
Also published as: CN116940779A; EP4305328A1; FR3120413A1; FR3120413B1

Abstract

The present invention relates to an expansion valve (12) intended to be arranged in a fluid passage (22) between an upstream conduit (18) and a downstream conduit (20), the expansion valve (12) comprising: - a tubular valve body (28) which is provided, in an upstream axial end section (32), with at least one upstream opening (34) intended to be in communication with the upstream conduit (18) and, in a downstream axial end section (36), with at least one downstream opening (38) intended to be in communication with the downstream conduit (20), the downstream opening (38) and the upstream opening (34) being connected by a main channel (30), - a shut-off device (40) which is movable between a closed position and an open position with respect to the downstream opening (20). The shut-off device (40) comprises a slide (42) which is axially slidably mounted on the downstream axial end section (36) of the valve body (28).

Description

DESCRIPTION

TITLE: EXPANSION VALVE COMPRISING A MOBILE SLIDE

Technical field of the invention

The present invention relates to an expansion valve.

The invention relates more particularly to an expansion and isolation valve provided for controlling the passage of a fluid between an upstream conduit and a downstream conduit, in particular when the fluid is subjected to high pressures.

Technical background

Different types of expansion and isolation valves are known to control the passage of a fluid. This type of valve is used in particular to expand a gas or perform an on-off all-or-nothing function.

In the case of applications under high pressure, as soon as a mobile surface is subjected to a differential pressure, the forces to be mobilized are considerable, which requires the use of an actuator with a high torque and which increases the risks of jamming. .

There is therefore a need for a simple and economical solution which makes it possible to control an expansion valve with a low torque actuator.

Also known are valves as disclosed in the documents EP0147357A2, WO2004/001260A1, and US5460349A.

Summary of the invention

To solve the problem mentioned above, the invention proposes an expansion valve intended to be arranged in a fluid passage between an upstream conduit and a downstream conduit, the expansion valve comprising:

- a tubular valve body which is provided, in an upstream axial end section, with at least one upstream orifice intended to be in communication with the upstream duct and, in a downstream axial end section, at least one downstream orifice provided to be in communication with the downstream duct, the downstream orifice and the upstream orifice being connected by a main channel,

- a closure device which is movable between a closed position and an open position with respect to the downstream orifice, characterized in that the closure device comprises a slider which is axially slidably mounted on the downstream axial end section of the valve body, between the closed position in which an axial wall of the slide closes the downstream orifice and the open position in which the axial wall of the slide releases the passage between the downstream duct and the downstream orifice, and in that the downstream axial end section of the valve body comprises, in the vicinity of the downstream orifice, a recess provided to cause progressive and controlled expansion when the expansion valve is opened, the downstream orifice extending radially between the main channel and the recess, the downstream axial end section of the valve body comprising a frustoconical section of decreasing outside diameter from upstream to downstream as far as the downstream orifice.

The expansion valve according to the invention makes it possible to withstand particularly high pressure differentials without requiring an actuator with a very high torque. Depending on the configuration of the recess, it is possible to choose the degree of progressiveness of the expansion with great finesse, which makes the expansion valve usable for many applications.

Another advantage of the expansion valve according to the invention is that it can be reversible and used in both directions of fluid circulation.

According to other advantageous characteristics of the invention:

- The axial wall of the slide defines a cylindrical bore whose diameter is between the largest diameter and the smallest diameter of the frustoconical section;

- the downstream axial end of the valve body is provided with a radial sealing element which cooperates in leaktight manner by sliding with the cylindrical bore; - the sealing element comprises a friction ring, for example made of polytetrafluoroethylene, which is pressed against the cylindrical bore by an elastic return element;

- the downstream axial end section of the valve body comprises an axial extension and a retaining element which is fixed to the axial extension and which axially retains the sealing element on the valve body;

- the elastic return element consists of an annular seal made of an elastomer type material;

- the friction ring has an internal annular groove in which part of the elastic return element is housed;

- the downstream axial end section of the valve body comprises an axial extension and the downstream axial extension of the valve body comprises an outer annular groove in which part of the elastic return element is housed;

- the valve body comprises a surface forming a seat, between the downstream axial end section and the upstream axial end section, an upstream axial end of the slide coming into leaktight axial bearing against the seat in the closed position;

- the slide has at least one vent which connects the inside and the outside of the slide to the downstream end of the expansion valve;

- the vent extends radially in the axial wall of the slider;

- the slider comprises an anti-rotation device designed to cooperate with a fixed element when the slider slides between its closed position and its open position so as to prevent rotation of the slider relative to the valve body;

- the valve body comprises several downstream orifices distributed circumferentially;

- the valve is of the bidirectional type, the expansion being able to be carried out from the upstream conduit towards the downstream conduit and from the downstream conduit towards the upstream conduit.

The invention also proposes a valve assembly comprising:

- an expansion valve,

- an actuator capable of controlling the expansion valve in the open position or closed,

- an assembly body comprising an upstream conduit and a downstream conduit, and comprising a housing capable of receiving the expansion valve, characterized in that the expansion valve is produced according to any one of the preceding characteristics, the actuator being connected to the slider to control its sliding between its open position and its closed position.

According to an advantageous characteristic of the valve assembly, the inside diameter of the housing is slightly greater than the outside diameter of the slider, so as to form a passage for the fluid from the downstream pipe to the inside of the slider through the vents ensuring a pressure balance between the inside and the outside of the slider.

Brief descriptions of figures

Other characteristics and advantages of the invention will appear during the reading of the detailed description which will follow for the understanding of which reference will be made to the appended drawings in which:

[Fig.1] - Figure 1 is an exploded perspective view which schematically shows a valve assembly equipped with an expansion valve according to a first embodiment of the invention;

[Fig.2] - Figure 2 is an axial sectional view along section plane 2-2 which shows the valve assembly of Figure 1 in the closed position; [Fig.3] - Figure 3 is a view similar to that of Figure 2 which shows the valve assembly of Figure 1 in the fully open position;

[Fig .4] - Figure 4 is a view similar to that of Figure 2 which shows a second embodiment of the expansion valve in the closed position;

[Fig.5] - Figure 5 is a view similar to that of Figure 4 which shows the second embodiment of the expansion valve in the fully open position; [Fig.6] - Figure 6 is a perspective view which schematically shows the valve body and its slot according to the second embodiment.

Detailed description of the invention

Figures 1 to 3 show a valve assembly 10 made in accordance with a first embodiment of the invention. The valve assembly 10 includes an expansion valve 12 which is inserted into a housing 14 provided in a mounting body 16.

The assembly body 16 comprises an upstream conduit 18, on the left when considering the figures, and a downstream conduit 20, on the right when considering the figures, each of which opens into a part of the housing 14. The valve assembly 10 thus comprises a fluid passage 22 formed by the upstream conduit 18, the downstream conduit 20, and the expansion valve 12.

The housing 14 here opens onto an upper face 24 of the assembly body 16 to allow the insertion of the expansion valve 12 into the housing 14. An actuator 26 is here mounted on the upper face 24 so as to be able to control the valve of trigger 12 in the open or closed position.

In the remainder of the description, use will be made, without limitation, of an orientation from upstream to downstream along the fluid passage 22. Of course, the valve assembly 10 and the expansion valve 12 are designed to operate in both directions, so that the choice of downstream and upstream are arbitrary and are intended solely to facilitate the description of the figures.

We will also use, without limitation, an axial orientation from upstream to downstream, along the main axis A1 of the expansion valve 12, which corresponds to a vertical orientation from bottom to top considering Figures 1 to 3 .

The expansion valve 12 comprises a tubular valve body 28 forming a main channel 30 along the main axis A1. The valve body 28 comprises an upstream axial end section 32 which is provided with an upstream orifice 34 in communication with the upstream conduit 18. The upstream axial end section 32 here forms a substantially cylindrical base which is received in a complementary manner in the bottom of the housing 14 so that the upstream orifice 34 opens into the upstream duct 18. The upstream orifice 34 here corresponds to the upstream axial end of the main channel 30.

The valve body 28 comprises a downstream axial end section 36 which is provided with at least one downstream orifice 38 intended to be in communication with the downstream pipe 20, when the expansion valve 12 is in the open position, as illustrated by FIG. 3. Advantageously, the downstream axial end section 36 here comprises four downstream orifices 38 which extend radially and which are distributed circumferentially every ninety degrees.

The expansion valve 12 is equipped with a closure device 40 which is movable relative to the downstream orifices 38 between a closed position, illustrated by figure 2, and an open position, illustrated by figure 3.

The closure device 40 comprises a slider 42 which is mounted to slide axially on the downstream axial end section 36 of the valve body 28, between the closed position in which an axial wall 44 of the slider 42 closes the downstream orifices 38 and the open position in which the axial wall 44 of the slider 42 frees the passage between the downstream orifices 38 and the downstream duct 20.

The axial wall 44 of the slider 42 here has a tubular cylindrical shape with a circular profile and thus delimits a cylindrical bore 46 inside.

The downstream axial end section 36 of the valve body 28 comprises, in the vicinity of the downstream orifices 38, a recess 48 provided to cause progressive and controlled expansion when the expansion valve 12 is opened. shown, the downstream axial end section 36 comprises a frustoconical section 50 of decreasing outside diameter from upstream to downstream as far as the downstream orifices 38. Thus, the recess 48 is formed in the radial space delimited by one side by the tapered section 50 and on the other by the cylindrical bore 46.

The cylindrical bore 46 here has a diameter slightly smaller than the largest diameter of the frustoconical section 50 so that, in the closed position, the axial wall 44 of the slider 42 can be in sealed contact with the base of the frustoconical section 50, at the downstream axial end of the slider 42. It there is therefore no passage of fluid between the recess 48 and the downstream conduit 20. The fluid coming from the main channel 30 is trapped in the recess by the axial wall 44 of the slider 42 and retained on the upstream side by the contact between the axial wall 44 and the valve body 28, and on the downstream side by a radial sealing element 52.

The sealing element 52 is here arranged at the downstream axial end of the valve body 28. It ensures static sealing and dynamic sealing by sliding against the cylindrical bore 46.

The sealing element 52 here comprises a friction ring 54, preferably made of polytetrafluoroethylene, which is pressed against the cylindrical bore 46 by an elastic return element 56. The elastic return element 56 here consists of a annular seal in elastomeric material, or O-ring.

The friction ring 54 has the particular advantage of contributing to the axial sliding guidance by its friction against the slider 42. According to the embodiment shown, the sealing element 52 is retained axially on the downstream axial end section 36 by a retaining element 58, here a washer set on an axial extension 60 in the form of a cylindrical pin. The retaining element 58 can be crimped thanks to a riveting operation applied to the free end of the axial extension 60.

The slider 42 here comprises, at its downstream axial end, a transverse plate 62 provided with a threaded hole 64. The actuator 26 comprises an actuating rod 66 here forming an endless screw provided to cooperate with the threaded hole 64 of so as to cause the slider 42 to move along the main axis A1.

Thus, when the actuating rod 66 is rotated in the direction of screwing, it causes the axial sliding of the slider 42 from upstream to downstream, between the closed position of Figure 2 and the position of opening of Figure 3. Conversely, when the actuating rod 66 is rotated in the direction of unscrewing, it causes the axial sliding of the slider 42 from downstream to upstream. The transverse plate 62 is extended here by two transverse arms 68 which form an anti-rotation device for the slider 42. These transverse arms 68 are received in complementary slides 70 arranged on the walls of the housing 14 which makes it possible to guide the slider 42 in the upper part 72 of the housing 14 during the rotation of the actuating rod 66.

Of course, other actuation solutions and another anti-rotation device solution could be provided to replace those described here.

Advantageously, the slider 42 comprises at least one vent 74, here two vents 74, which connect the inside and the outside of the slider 42 to the downstream end of the expansion valve 12. The vents 74 here consist of holes radials in the axial wall 44, just below each transverse arm 68.

Advantageously, the outer diameter of the slider 42, at its axial wall 44, is slightly smaller than the corresponding inner diameter of the housing 14 so as to allow a passage of fluid from the downstream conduit 20 to the upper part 72 of the housing 14 , and to the inside of the slide through the vents 74, whatever the position of the slide 42. This makes it possible to ensure a pressure balance on either side of the transverse plate 62 so that the actuator 26 does not have to provide a significant effort during an opening or closing phase of the expansion valve 12 due to the pressure differential between the upstream conduit 18 and the downstream conduit 20.

We will now describe the operation of the valve assembly 10 according to the first embodiment from the closed position which is illustrated in Figure 2.

In the example shown, in the closed position, it is considered that the upstream conduit 18 is at a first pressure P1 different from the second pressure P2 in the downstream conduit 20. The valve assembly 10 according to the invention is capable of operating with a very high pressure differential between the upstream conduit 18 and the downstream conduit 20, for example a pressure differential of 160 bars. In the closed position, the upstream conduit 18, the main channel 30, and the recess 48 are all at the same pressure, that is to say here the first pressure P1. The sealed contact between the axial wall 44 and the base of the frustoconical section 50, and the sealed contact between the friction ring 54 and the cylindrical bore 46 prevent the circulation of the fluid between the upstream and the downstream.

The downstream duct 20, the radial space 76 between the slider 42 and the housing 14, the upper part 72 of the housing 14, the inside of the slider 42, are all at the same pressure, that is to say here the second press P2.

When the progressive opening of the expansion valve 12 is controlled, the actuator 26 causes the slider 42 to slide downstream, that is to say upwards considering FIGS. 2 and 3. sliding downstream, the slider 42 progressively uncovers the recess 48 which allows progressiveness in the expansion of the fluid which begins to pass progressively from the upstream conduit 18 to the downstream conduit 20, or the reverse depending on the differential of pressure.

It is noted that the progressiveness of the relaxation depends on the inclination of the wall of the frustoconical section 50 with respect to the cylindrical bore 46. The lower this inclination, the more the relaxation will be progressive. Indeed, the passage section of the fluid between the frustoconical section 50 and the cylindrical bore 46 increases progressively when the slider 42 moves downstream.

The slider 42 continues its stroke to the fully open position which is shown in Figure 3. Advantageously, in the fully open position, the slider 42 is offset axially downstream with respect to the downstream orifices 38 of so as to uncover them completely and thus maximize the passage section of the fluid between the downstream and the upstream.

Of course, the valve assembly 10 operates similarly in the reverse direction, as the slider 42 moves from the open position to the closed position.

The expansion valve 12 according to the invention therefore has the advantage of being able to be bidirectional and allow control of the expansion of the fluid whether in the upstream to downstream direction or in the downstream to upstream direction. In a first case, the first pressure P1 is greater than the second pressure P2, in a second case the first pressure P1 is lower than the second pressure P2.

Figures 4 to 6 show a second embodiment of the valve assembly 10 according to the invention. Only the main elements which differentiate the second embodiment from the first will now be described.

In the second embodiment, the valve body 28 has a cylindrical shape of circular section and not a frustoconical section, as shown in Figure 6. The progressiveness of the expansion is obtained by fitting on the outer axial wall of the body of valve 28 a recess 48 in the form of a slot 78 which gradually widens downstream until it reaches the height of the downstream orifices 38. Thus, during an opening phase, the slider 42 begins to first by uncovering the bottom of the slot 78, which has a very small passage section, then the top of the slot 78 which has a larger passage section, until all the downstream orifices 38 are uncovered, as shown in the figure 5.

The second embodiment is also distinguished by the arrangement of the friction ring 54 and its retention on the valve body 28. Here the friction ring 54 comprises an internal annular groove 80 in which a part of the elastic element of recall 56 comes to stay. The axial extension 60 of the valve body 28 here comprises an outer annular groove 82 in which part of the elastic return element 56 is housed. The retaining element 58 here consists of a nut which is screwed onto the axial extension 60, replacing the crimped washer used in the first embodiment. In this second embodiment, the valve body 28 may comprise a surface forming a seat on which the slider 42 comes into sealed axial support in its closed position.

The operation of the valve assembly 10 according to the second embodiment is identical to that described for the first embodiment.

LEGEND 10: valve assembly

12: expansion valve

14: housing

16: mounting body

18: upstream pipe

20: downstream pipe

22: fluid passage

24: upper face

26: actuator

28: valve body

30: main channel

32: upstream axial end section

34: upstream port

36: downstream axial end section

38: downstream port

40: shutter device

42: slider

44: axial wall

46: cylindrical bore

48: recess

50: tapered section

52: sealing element

54: friction ring

56: elastic return element

58: retainer

60: axial extension

62: cross plate

64: tapped hole

66: actuating rod

68: transverse arm

70: slides

72: upper part

74: vent 76: radial gap

78: slit

80: inner annular groove 82: outer annular groove A1: main axis P1: first pressure P2: second pressure

Claims

1. Expansion valve (12) intended to be arranged in a fluid passage (22) between an upstream conduit (18) and a downstream conduit (20), the expansion valve (12) comprising:

- a tubular valve body (28) which is provided, in an upstream axial end section (32), with at least one upstream orifice (34) intended to be in communication with the upstream pipe (18) and, in a downstream axial end section (36), of at least one downstream orifice (38) provided to be in communication with the downstream duct (20), the downstream orifice (38) and the upstream orifice (34) being connected by a main channel (30),

- a closure device (40) which is movable between a closed position and an open position with respect to the downstream orifice (20), characterized in that the closure device (40) comprises a slider (42) which is axially slidably mounted on the downstream axial end section (36) of the valve body (28), between the closed position in which an axial wall (44) of the slider (42) closes the downstream orifice (38) and the open position in which the axial wall (44) of the slider (42) frees the passage between the downstream duct (20) and the downstream orifice (38), and in that the downstream axial end section (36) of the body valve (28) comprises, in the vicinity of the downstream orifice (38), a recess (48) provided to cause a gradual and controlled expansion when the expansion valve (12) is opened, the downstream orifice ( 38) extending radially between the main channel (30) and the recess (48), the downstream axial end section (36) of the valve body (28) comprising a section frustoconical (50) with an outside diameter decreasing from upstream to downstream to the downstream orifice (38).

2. Expansion valve (12) according to the preceding claim, characterized in that the axial wall (44) of the slider (42) defines a cylindrical bore (46) whose diameter is between the largest diameter and the smallest diameter of the frustoconical section (50) so as to ensure sealed contact between the axial wall (44) and the tapered section (50) in the closed position.

3. Expansion valve (12) according to the preceding claim, characterized in that the downstream axial end of the valve body (28) is provided with a radial sealing element (52) which cooperates in a leaktight manner by sliding with the cylindrical bore (46).

4. Expansion valve (12) according to the preceding claim, characterized in that the sealing element (52) comprises a friction ring (54), for example of polytetrafluoroethylene, which is pressed against the cylindrical bore (46 ) by an elastic return element (56).

5. Expansion valve (12) according to claim 3 or claim 4, characterized in that the downstream axial end section (36) of the valve body (28) comprises an axial extension (60) and a retaining element (58) which is attached to the axial extension (60) and which axially retains the sealing element (52) on the valve body (28).

6. Expansion valve (12) according to any one of claims 3 to 5, characterized in that the elastic return element (56) consists of an annular gasket made of material of the elastomer type.

7. Expansion valve (12) according to any one of the preceding claims, characterized in that the slider (42) comprises at least one vent (74) which communicates the interior and the exterior of the slider (42) to the downstream end of the expansion valve (12).

8. Expansion valve (12) according to the preceding claim, characterized in that the vent (74) extends radially in the axial wall (44) of the slider (42).

9. Expansion valve (12) according to any one of the preceding claims, characterized in that the slider (42) comprises an anti-rotation device (68) provided to cooperate with a fixed element (70) during sliding of the slider (42) between its closed position and its open position so as to prevent rotation of the slider (42) relative to the valve body (28).

10. Expansion valve (12) according to any one of the preceding claims, characterized in that the valve body (28) comprises several downstream orifices (38) distributed circumferentially.

11. Expansion valve (12) according to any one of the preceding claims, characterized in that it is of the bidirectional type, the expansion being able to be carried out from the upstream conduit to the downstream conduit and from the downstream conduit to the upstream conduit .

12. Valve assembly (10) comprising:

- an expansion valve (12),

- an actuator (26) capable of controlling the expansion valve (12) in the open or closed position

- an assembly body (16) comprising an upstream conduit (18) and a downstream conduit (20), and comprising a housing (14) capable of receiving the expansion valve (12), characterized in that the expansion valve ( 12) is made according to any one of the preceding claims, the actuator (26) being connected to the slide (42) to control the sliding thereof between its open position and its closed position.

13. Valve assembly (10) according to the preceding claim taken in combination with claim 7, characterized in that the inside diameter of the housing (14) is slightly greater than the outside diameter of the slider (42), so as to form a passage for the fluid from the downstream pipe (20) to the inside of the slider (42) through the vents (74) ensuring a pressure balance between the inside and the outside of the slider (42).